DE1202311B - Method and circuit arrangement for the most error-free transmission possible of binary impulse-shaped signals over temporarily heavily disturbed channels - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. α .:

H04b

H041

German class: 21 al - 7/06

Number:
File number:
Registration date:
Display day:

St 16179 VIII a / 21 al

March 2, 1960

October 7, 1965

The invention relates to the transmission of pulsed signals which are in binary form. Such signals are primarily teletype characters, but also any other signals that the reproduce the message content to be transmitted in the form of a binary pulse code.

The binary form of message transmission is also subject to interference, which results in falsification individual steps, i.e. the individual binary statements, can be made noticeable.

In recent times, namely in connection with electronic automation, the importance is the so-called data transmission has grown considerably. A typical task is that Data from remote locations are to be reported to a control center with a data center, in which these Data is processed in some way and reported back from the evaluation results or to be passed on to other places. This task occurs, for example, in connection with the Booking of means of transport, primarily flight booking, within the framework of the weather service and in business, for example at department store groups or in connection with chain stores.

In view of the expected large number of users for data transmission connections or networks, which may be large distances to be bridged and which as a rule for the Consumer prohibitively high costs for the creation of special, wired, high quality Transmission channels, the planning must assume from the outset that either radio channels or already existing wired channels, d. H. the telephone network. So is in Within the scope of the invention, in particular, but by no means exclusively, to selected telephone connections intended as transmission channels. It is clear that on such connections - i. H. so on Radio connections and on selected telephone channels - strong interference is to be expected. The nature of these disturbances will be discussed later.

The point of such data transmission stands or falls with the possibility of transmission errors largely excluded. The basic task is to work over a possibly large distance to make the duplicate of a binary message record. “Transmission error "largely excluded" therefore means more precisely, since their exclusion is absolutely not possible In other words: create a sufficient probability that the result of the transference is that of the

Method and circuit arrangement for
as error-free as possible transmission of binary
pulse-shaped signals over temporarily strong
disturbed channels

Applicant:

Standard Elektrik Lorenz Aktiengesellschaft,
Stuttgart-Zuffenhausen, Hellmuth-Hirth-Str. 42

Named as inventor:

Dr.-Ing. Hans Marko, Stuttgart-Stammheim;

Herbert Aulhorn, Stuttgart-Weilimdorf

Duplicate recorded at the receiving station with the binary recording at the sending station coincides although with interference, d. H. Transmission errors, must be expected.

Processes are already known which aim to achieve this result. They are all at the expense of the transmission time, which, however, in some cases - exchanged for bandwidth through parallel transmission can be.

In principle, simple procedures consist in using all characters or groups of characters in parallel or series operation (in this case recording is essential before evaluation) several times, d. H. to send at least twice, to check the reception results for identity and if there is no Identity to request repetitions of the characters or groups of characters until there is a sufficient probability for error-free reception.

Such methods are extremely expensive in terms of transmission time and / or bandwidth. Codes have also been developed which make it possible to detect errors on the receiving side. The principle is that the code characters contain more elements (steps) than for Representation of the given number of characters to be distinguished would be necessary (redundancy). Just a certain one The number of possible step combinations is therefore actually the characters to be transmitted assigned. Only they "are in the code book" as correct

509 690/313

valid characters, and the transmission can then, and only then, have been error-free if there is one in the code was received as a "correct" contained character. One that is not listed as "correct" in the code book Character is certainly flawed. The greater the redundancy of the code, the greater the likelihood that errors are recognized. The increase in the number of steps per character is at the expense of time in series operation, in parallel operation at the expense of bandwidth.

If you are satisfied with error detection, the characters recognized as defective must be repeated which of course requires additional time in any case.

So-called self-correcting codes are also already known, i.e. codes whose structure and redundancy make it possible to provide facilities on the receiving side that to a certain extent and with a certain probability from the received incorrect character to the sent one correct and evaluate accordingly. They are the classic examinations of Hamming known who answered the question, how a code must be structured that allows a certain number of redundancies of errors in the sign can still be recognized. There remains a likelihood of occurrence of undetectable errors that simply have to be accepted so that these principles are theirs Limits to the demand made with regard to the smallness of the probability of not recognized Errors on the one hand and the size of the disturbances, d. H. the size of the step error probability, on the other hand find.

The generally intended test method consists of the so-called checksum test. Hereinafter let us denote the two binary alternatives of a step with 0 and 1 as usual. Even the checksum test is based on the individual code character and consists in that each character either a certain number according to the code - even or odd, in the example "even" assumed - from z. B. contains 1-steps or by adding a suitable one at the sending end Test step is brought to the specific number and that it is checked at the receiving end whether this number is available. If this is not the case, then the symbol is definitely wrong. on in this way, of course, only odd numbers of errors are recognizable in the character, while numbers of errors are even pretend to be a correct sign. For this reason, it is already known through checksum checking steps protected characters (with a certain probability "protected" from the fact that a character that has become faulty due to the transmission is regarded as fault-free on the receiving side and is evaluated) in so-called blocks.

As a flat block, they then form a matrix, the rows (or columns) of which are each marked by a character together with its test step, while the columns (or rows) are now still formed by test steps can be protected and thus a checksum check is possible in both dimensions. It is it is evident that this increases the likelihood of fault detection. You can also be in the plane can be increased even further by also protecting the diagonals through test steps. Even Knight jumping methods are possible. Finally, you can use a cubic instead of an area matrix provide.

The entire block is now checked. Er-S shows this to be faulty, so it is repeated. Nevertheless, the basis for the corresponding proposals that have become known remains the individual Characters and their code, as well as the principle that the choice of code and its redundancy depends on the

ίο assumed probability of step error on the one hand and the required character error probability on the other hand. With the character length is but also determines the block length in at least one dimension.

If the probability of step error is too high (the highest possible is 0.5), then one is error-free transmission not possible at all. But now the z. B. on radio links and selected telephone lines applicable case that with any, so also extremely high Step error probabilities only need to be calculated in a fraction of the total time that occurs at statistically distributed intervals of the total time. Between these severely disturbed intervals there are therefore intervals in which a transmission is possible.

The known checksum check described above, including the block formation, which is based on the admission of a certain maximum step error probability, fails in this case. A very high value, moving towards 0.5, would have to be provided as the probability of a step error, which would lead to a completely unacceptable redundancy and thus to prohibitive expenditure. Otherwise, however, characters transmitted in time intervals of the strongest interference, which are most likely to be falsified, could not be recognized as faulty. The task therefore arises of creating a method for the most error-free transmission of binary pulse-shaped signals via channels that are at times heavily disturbed. The invention makes use of the formation of blocks and the repetition of blocks recognized as faulty. The invention is characterized in that the pulse signals occurring in series on the transmit side regardless of the message content and the predetermined classification as a protected block, its number of signals («) and redundancy (R) in accordance with the required block error probability, the selected protection scheme and, if required, the available storage capacity are selected, are written into a memory and that the blocks are transmitted, stored at the receiving end and checked on the basis of the protection scheme.

What is fundamentally new compared to known methods is that any random step error probability is allowed. There is therefore no maximum probability of step error more, from which the required probability of error detection is no longer ensured is.

So there is no longer any specific code and redundancy that make it safe Recognition of a given number of errors in individual characters. Rather, the single sign occurs completely in the background and is not treated as such, in particular not protected. Instead of

of which blocks are formed, their message content not known, therefore not listed in a code book, and by a purely statistical basis working method protected, whereby the block error probability is selectable or prescribed. The fault does not need to be localizable and it is not. With a given block error probability the redundancy can no longer be specified, it can only be based on

The curves for η = 64, R = 2.37 and η = 125, R - 1.95 are excellent. They have maxima of the block error probability lying on a straight line. Only the maximum points are entered for the remaining parameter pairs.

Fig. 2 shows a diagram in which the meaning 1, the maximum block error probability is plotted against the redundancy. The three curves are various block shapes associated with

various factors, including the type of protection io assigned to a respective protection scheme. Schemas and the possible and appropriate The curve on the right applies to the case of Fig. 1,

Block length, a compromise that d. H. Cube with 3 parity check. The middle curve also at a technically acceptable value of the redundancy applies to a flat matrix with rows, columns and danz leads. Diagonal protection, i.e. a triple check of checksums

The new starting point is the required 15 or 3 parity check. The curve on the left applies to a limit of the block error probability, the flat matrix with only row and column protection with the maximum possible step error probability (2-parity check). The (0.5) written in the curves must not be exceeded. That is, with numerical markings, the number of steps η in other words: The starting point is the requirement, block, i.e. the block length, for which the respective that the greatest disturbance and the ordinate values also apply in time intervals.

with the greatest possible step error probability The following can be seen from FIG. 1: One has

the probability that errors will not be recognized for a certain block shape (here the cube) is reduced to a required minimum and a certain protection scheme (here 3-parity remains. But this is the prerequisite for the data check) can be decided with the required transmission over channels on which such a maximum block error probability (let it be intervals of the greatest disturbances occur sporadically. ΙΟ "" ¹⁰ ) enter the diagram and read it off,

According to this value, i.e. the permitted block, which block length and which redundancy pre-error probability, are now based independently. In the example, these are η = 125 and the message content, the type of code and R = 1.95. With these values, the required length of the original character division (ie 30 limit of the block error probability for each number η of the message and test steps) and any step error probability is maintained, the block that is defined by the test steps as
Whole is protected. Only the selected protection scheme and, if required, a given storage capacity are of secondary importance for length and shape
of the block is decisive.

It is evident that the independence of the procedure from the message content, from the type of Codes and the original character division should be seen as an additional advantage.

The principles of the invention and a schematic embodiment will now be based on the Drawings are explained in more detail.

Figs. 1 and 2 are diagrams for explaining the relationships between the block error probability and the step error probability, the block length, the redundancy and the chosen Protection scheme;

Fig. 3a shows a diagram for selected telephone lines the connection between block 5 ° error-free transmission is possible. Are the blocks long and disturbed transmission time, too long, so there are too many faulty transmissions,

Fig. 3b shows the percentage distribution of the lengths in the extreme case only faulty transmissions, undisturbed time intervals; The diagrams in FIGS. 3a and 3b give tasks

F i g. 4 shows the block diagram of a transmission and conclusion of the result of examinations Receiving arrangement for carrying out the method 55 the interference conditions on selected telephones according to the invention; cables.

Fig. 5 is a diagram to explain the Fig. 3a shows the relative number of disturbed

Mode of operation of the arrangements of Fig. 4. Blocks and thus the resulting from the disturbances

In the diagram of FIG. 1 is the block error detected loss of transmission time depending on

probability P _m as a function of the step error probability on the block length. For blocks of some

probability ρ plotted. a hundred milliseconds in length it is less than 5%.

It is based on the block shape of the cube Fig. 3b shows how the trouble-free

and as a protection scheme the checksum check in total time for interference-free intervals of certain divides the three spatial dimensions (cube with lengths. One recognizes that on average with 3-parity check). The parameter is the block length, 65 interference-free intervals of 15 to 20 seconds given as parameter pairs that may be included in the block.

Number of steps η and the redundancy R - n / m, where m

is the number of information steps. carrying step speed, for further training

This means that the required probability of recognizing errors is maintained for every degree of interference will.

By making the system "better" than required, that is, by making the block error probability lower than required, you can still exchange between block length and redundancy make, d. H. technically-practically speaking: between storage capacity and thus costs and effort and transfer time. Because the higher the redundancy, the higher the number the steps that have no actual message content.

There is another practical limit to the choice of block length, and that is an upper limit Border; it must be in a reasonable proportion to the length of those time intervals in which the transmission path is so little disturbed that one

of the method according to the invention still has a lower limit for the choice of the block length. This training is for the transmission on channels that operate in opposite directions, i.e. simultaneous transmission in Allow both traffic directions, suitable and consists in the fact that the transmitter and receiver are rigid are synchronized with each other that during the time interval that is used to transmit the return signal (Acknowledgment for error-free receipt or request for repetition) is available, the next block is transmitted and that upon a request for repetition or if a response has failed after the block just transferred instead of the next Block a repetition identification signal is transmitted.

Since it must be clear for which block an acknowledgment or a repeat request signal must be given is to apply, the blocks must be that long or sent at such a speed that their transmission time is at least as long as the sum of the transit times of the forward and reverse channel.

Since the required length of this transmission time for a block is not primarily based on The cost of the transmission speed will want to achieve the above-mentioned lower result Limit for the block length to be selected.

Fig. 4 shows an embodiment for a transmitting and an associated receiving arrangement for implementation of the method according to the invention according to the development just outlined.

F i g. 5 is a related functional diagram.

It is assumed that the message is taken from a paper tape reader. The perforated tape enleserl (Fig. 4), like any other sequential memory, has its own rhythm and cannot are included in the clock of the transmission device, as well as the transmission device not can be synchronized to the clock of the tape reader. This independence from input memory and transmission system is very advantageous operationally. Also the type of coding that is carried out by Addition of the test steps on the sending side is done, subjecting the content of the input memory no requirement. The retrieved steps are protected regardless of whether the input store in turn contains proprietary code or not.

There are three transmission block memories TS1, TS 2 and TS 3 provided on the transmission side. Two synchronized with each other, offset from each other in their rhythm to a block interval switch Sl and S 2 are the cyclic connection of the memory to the tape reader 1 and - via the modulator 2 and the switch 3 - to the transmission channel. 4

A switch 53 is used to connect the tape reader 1 to the collective contact of the switch 51. Depending on its position, the changeover switch 54 sets either the collective contact of the switch 52, ie the block memory TS, or a memory RTS in which a repetition identification signal is stored , to the transmission channel.

The switches 51 and 52 are controlled by the clock generator 5. Switches 5 are 3 and 54 operated when there is a fault, by the control member 6 with synchronization from Clock 5 ago.

The transmission facilities as well as the synchronization character transmission can correspond to conventional technology. A series transmission is sought of the shortest possible impulses while making optimal use of what is available Frequency band. A double sideband modulation with transmission of the direct current component is preferably namely a narrowband frequency modulation in which practically only the sidebands 1st order to be transferred.

The transmission speed should be 800 Bd, with which for selected telephone connections presumably the upper limit has been reached.

The receiving arrangement, which begins with the switch 7 and the demodulator, is from a Clock generator 9 with divider rigidly connected to the transmitting arrangement in any known manner The frequency given by the walking speed is synchronized via a flywheel synchronizing device 10.

The receiving arrangement contains two receiving block memories RSa and RSb, which can be placed on the input side via the switch SS alternately to the output of the demodulator 8 and on the output side via the switch 56 to the switch 7 leading to the output device 11 (ζ. Β. Tape punch). The switches 55 and 56 are synchronized with one another in the manner shown in the figure. With a second contact, the switch 55 simultaneously applies the test device 12 to the memory that is on reception.

A coincidence circuit 13 is connected to the demodulator output and has the repetition indicator recognizes and synchronizes the clock generator 9 to block clock via the gate circuit 14.

If the test device 12 detects a faulty block, it delivers a signal to the control element 15, which actuates the switch 7 with synchronization from the clock 9.

At the same time, the test device 12 supplies a signal to the malfunction alarm switch 16.
Now let us first consider the reverse channel. A double-tone channel 4 'is provided for the return signaling, which works with the tones Z ₁ and / ₂ and which is subordinate to the forward channel in the frequency multiple (switches 3 and 7). As long as the system is working properly and no reception error has been detected, tone Z ₁ is continuously transmitted back. If an error occurs, it is interrupted and replaced by the interference signal, the tone Z ₂ .

The interference alarm receiver stands accordingly

17 only not on alarm if he hears the tone Z ₁ ,

and this exclusively, receives. It therefore shows an alarm if Z ₁ and / _{2 are} missing, when Z ₁ and Z _{2 are received} and only / _{2 is received} .

The arrangements for generating and receiving the two tones Z ₁ and Z ₂ are denoted by 18 and 19 and 20 and 21, respectively. A transmit and a receive amplifier for the return channel are denoted by 22 and 23, respectively.

The fault signaling in the case of an error detection now goes, as already stated, from the test device 12 by delivering a signal to the fault alarm switch 16.

This then interrupts the TOnZ ₁ and allows the tone Z ₂ to be transmitted as an interfering signal. As a result, the nuisance alarm receiver 17 speaks

and supplies a signal to the control member 6, which in turn actuates the switch S 4 , whereby the transmission channel 4 is applied to the memory RTS , so that the repetition identification signal is transmitted and received by the coincidence circuit 13 and recognized. The latter reports to the interference alarm switch 16 that a repetition identification signal has been correctly recorded and recognized, which then _{interrupts the transmission of the interference signal, the tone / 2} , and brings the tone Z ₁ to the transmission again.

The timing of the switching operations is shown in the function diagram of FIG. The line α indicates which of the consecutive (only for this illustration) numbered blocks are sent; in the times when the repetition identification signal is sent, the number of the block that is skipped is noted in brackets. Lines b and c identify the state of the two return channels on the transmitting side, that is to say in the interference alarm receiver 17, the thick line meaning "sound" and the thin line "no sound". As can be seen, the return signal "reception correct" is synonymous with "sound" in channel Z ₁ and "no sound" in channel Z ₂ .

The two following lines d and e indicate which return signal is sent back from the receiving end. The indicated states are shifted by the (maximum permissible) runtime compared to those of the sending side.

Line g specifies how each individual block is evaluated on the receiving end: A digit or the character "0" indicates that the block is regarded as "correct" and the repetition identification signal "0" as such (due to coincidence in 13) was recognized. "?" Means that an error was detected; to make it easier to understand, to the right of the "?" it is indicated which block is disturbed (information that the recipient is of course missing).

Line h shows which block is released and transferred from the receiving memory to the output memory (e.g. tape punch 11). An arrow from line g to line h indicates that the transfer to the output memory is blocked for the time of a 3-block cycle.

The following was shown: The repeat request due to a fault in a block (No. 4); repetition due to disturbance in the return channel:

a) "Sound" in both channels (block no. 8),

b) "no sound" in both channels (block 12);

Disturbance of seven successive blocks (line g, after block 12; disturbance of a block (no. 17) and the first "O" signal.

The last example is important because it shows why, after a single block has been disrupted (cf. Block no. 4) six block times must be lost: The recipient cannot distinguish whether a block is incorrect because of interference pulses or because of a synchronization error is addressed. It must therefore be forced to check the synchronization by the nuisance alarm is only canceled after an »O« signal has been properly received.

Claims (4)

65 claims: 1. A method for the most error-free transmission of binary pulse-shaped signals over temporarily heavily disturbed channels with block formation and repetition of blocks that are found to be faulty on the receiving side, characterized in that the pulse signals occurring in series on the transmitting side, regardless of message content and predetermined classification as a protected block whose number of steps (n) and redundancy (R) are selected in accordance with the required block error probability, the selected protection scheme and, if required, the available storage capacity, are written into a memory and that the blocks are transmitted, stored on the receiving side and checked on the basis of the protection scheme . 2. The method according to claim 1 for the transmission on channels that have counter operation (simultaneous transmission in both directions of traffic), characterized in that that the blocks are chosen so long or are sent at a speed that their Transmission time is at least as long as the sum of the transit times of the forward and reverse channels, that the transmitter and receiver are rigidly synchronized with one another that during the time interval that is used to transmit the return signal (Acknowledgment for error-free receipt or request for repetition) is available stands, the next block is already being transferred and that on a request for repetition or if a response has failed, after the block just transferred in place of the a repetition identification signal is transmitted in the next block. 3. Transmitter arrangement for performing the method according to claim 2, characterized in that three block memories (TSl, TS 2, TS 3) are provided into which is written in a rigid cycle and from which in a rigid cycle (ie in unchanged order) for the purpose of transmission It is queried that a memory (RTS) is also provided on the transmission side, in which the repetition identification signal is of block length and which can be connected to the transmission path (4) instead of a block memory, for as many block lengths as the receiver via the Return channel requests block repetitions, and that means (17, 6, S3) are provided which prevent a block memory from being erased and reassigned before the acknowledgment signal for the block previously stored in it has been received. 4. Receiving arrangement for carrying out the method according to claim 2 in cooperation with the transmitting arrangement according to claim 3, characterized in that two receiving block memories (RSa, RSb) are provided into which - according to memory and function, everything in rigid change - is written , in which it is checked and from which it is stored out to the output device (11) that an acknowledgment is given for the test result "block error free", and for the test result "block incorrect" the repeat request is given to the transmitter via the return channel (4 '), and that means (12, 13, 14 15, S 7) are provided, after a repeat request has been sent and a repeat request has not been received 509 690/313 if the repetition identification signal is triggered to prevent the storage for three block intervals, however, repeat requests and received repeat identification signals that are received on End of the first and second of the affected 12th Block intervals occur or are recognized, do not trigger such an effect. Documents considered: German Auslegeschrift No. 1044 469. For this purpose 2 sheets of drawings 509 690/313 9.65 © Bundesdruckerei Berlin